Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-30T01:33:18.075Z Has data issue: false hasContentIssue false
  • English
  • Français

Changes in the gelation mechanism of whey protein concentrate with pH and temperature

Published online by Cambridge University Press:  01 June 2009

Stephen M. Taylor ,
Lynn F. Gladden  and
Peter J. Fryer
Stephen M. Taylor
Affiliation:
Department of Chemical Engineering, University of Cambridge, Pembroke Street, Cambridge CB2 3RA, UK
Lynn F. Gladden
Affiliation:
Department of Chemical Engineering, University of Cambridge, Pembroke Street, Cambridge CB2 3RA, UK
Peter J. Fryer
Affiliation:
Department of Chemical Engineering, University of Cambridge, Pembroke Street, Cambridge CB2 3RA, UK
Get access Rights & Permissions [Opens in a new window]

Summary

The percolation model of Steventon et al. (1991) successfully detected changes in the mechanism of whey protein concentrate gelation with pH and temperature by comparing simulated with experimental gelation times. The results demonstrated that at 71 °C and pH 5·2 the formation of an aggregate from two denatured protein molecules (initiation) was the rate-determining step in the gelation process, while at pH 7·0 the addition of denatured protein molecules to an aggregate (propagation) was rate-determining. At pH 5·9, the gelation process was also initiation limited, with the rate being slower than for pH 5·2 solutions, probably owing to electrostatic effects. Analysis of the temperature dependence of the gelation time, and percolation analysis both showed that there was a change in the rate-controlling reaction at 73 °C for gelation at pH 5·2 and 7·0. In the case of pH 7·0 gelation, this change in rate-controlling reaction was not due to a change from denaturation- to aggregation-controlled gelation, but was probably due to a change in the relative rates of interactions between protein molecules. Gelation at pH 5·2 was aggregation-controlled at temperatures below 73 °C, and denaturation-controlled at higher temperatures; there appeared to be another change in rate-limiting reaction at 80–85 °C without a change in mechanism (i.e. it remained denaturation-limited). The activation energies of the rate-limiting reactions determined from analysis of the temperature dependence of gelation time and from percolation analysis were in agreement. This is evidence that the changes in the rate-controlling reaction of whey protein concentrate gelation with temperature and pH were real.

Type
Original Articles
Information
Journal of Dairy Research , Volume 61 , Issue 1 , February 1994 , pp. 71 - 81
Copyright
Copyright © Proprietors of Journal of Dairy Research 1994

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Dannenberg, F. & Kessler, H. G. 1988 Reaction kinetics of the denaturation of whey proteins in milk. Journal of Food Science 53 258263CrossRefGoogle Scholar
De Wit, J. N., Hontelez-Backx, E. & Adamse, M. 1988 Evaluation of functional properties of whey protein concentrates and whey protein isolates. 3. Functional properties in aqueous solution. Netherlands Milk and Dairy Journal 42 155172Google Scholar
Dunkerley, J. A. & Hayes, J. F. 1980 Characterization of whey protein gels using a temperature gradient block. New Zealand Journal of Dairy Science and Technology 15 191196Google Scholar
Dunkerley, J. A. & Zadow, J. G. 1984 The effect of calcium and cysteine hydrochloride on the firmness of heat coagula from Cheddar whey protein concentrates. Australian Journal of Dairy Technology 39 4447Google Scholar
Dunnill, P. & Green, D. W. 1966 Sulphydryl groups and the N⇆R conformational change in β-lactoglobulin. Journal of Molecular Biology 15 147151CrossRefGoogle ScholarPubMed
Eigel, W. N., Butler, J. E., Ernstrom, C. A., Farrell, H. M., Harwalkar, V. R., Jenness, R. & Whitney, R. McL. 1984 Nomenclature of proteins of cow's milk. Fifth revision. Journal of Dairy Science 67 15991631Google Scholar
Ferry, J. D. 1948 Protein gels. Advances in Protein Chemistry 4 178Google Scholar
Flory, P. J. 1941 a Molecular size distribution in three dimensional polymers. I. Gelation. Journal of the American Chemical Society 63 30833090CrossRefGoogle Scholar
Flory, P. J. 1941 b Molecular size distribution in three dimensional polymers. II. Trifunctional branching units. Journal of the American Chemical Society 63 30913096CrossRefGoogle Scholar
Flory, P. J. 1941 c Molecular size distribution in three dimensional polymers. III. Tetrafunctional branching units. Journal of the American Chemical Society 63 30963101Google Scholar
Harwalkar, V. R. & Kalab, M. 1985 Microstructure of isoelectric precipitates from β-lactoglobulin solutions heated at various pH values. Milchwissenschaft 40 665668Google Scholar
Hillier, R. M. & Lyster, R. L. J. 1979 Whey protein denaturation in heated milk and cheese whey. Journal of Dairy Research 46 95102Google Scholar
Koning, M. M. G. & Visser, J. 1992 Protein interactions. An overview. In Protein Interactions, pp. 124 (Ed. Visser, J.). Weinheim, Germany: VCHGoogle Scholar
Lyster, R. L. J. 1970 The denaturation of α-lactalbumin and β-lactoglobulin in heated milk. Journal of Dairy Research 37 233243CrossRefGoogle Scholar
Manji, B. & Kakuda, Y. 1986 Thermal denaturation of whey proteins in skim milk. Canadian Institute of Food Science and Technology Journal 19 163166CrossRefGoogle Scholar
Mulvihill, D. M. & Kinsella, J. E. 1987 Gelation characteristics of whey proteins and β-lactoglobulin. Food Technology 41(9) 102111Google Scholar
Mulvihill, D. M. & Kinsella, J. E. 1988 Gelation of β-lactoglobulin: effects of sodium chloride and calcium chloride on the rheological and structural properties of gels. Journal of Food Science. 53 231236CrossRefGoogle Scholar
Oakenfull, D. & Scott, A. 1986 new approaches to the investigation of food gels. In Gums and Stabilisers for the Food Industry 3 (International Conference, 1985), pp. 465475 (Eds G. O. Phillips, D. J. Wedlock and P. A. Williams). London: Elsevier Applied ScienceGoogle Scholar
Park, K. H. & Lund, D. B. 1984 Calorimetric study of thermal denaturation of β-lactoglobulin. Journal of Dairy Science 67 16991706Google Scholar
Paulsson, M., Dejmek, P. & van Vliet, T. 1990 Rheological properties of heat-induced β-lactoglobulin gels. Journal of Dairy Science 73 4553Google Scholar
Plock, J., Beyer, H.-J. & Kessler, H.-J. 1992 Whey protein denaturation in milk protein solutions dependent on the casein/whey protein ratio and its influence on gelation. In Protein Interactions, pp. 167191 (Ed. Visser, J.). Weinheim, Germany: VCHGoogle Scholar
Richardson, R. K. & Ross-Murphy, S. B. 1981 Mechanical properties of globular protein gels: 1. Incipient gelation behaviour. International Journal of Biological Macromolecules 3 315322Google Scholar
Ross-Murphy, S. B. 1991 Physical gelation of synthetic and biological macromolecules. In Polymer Gels: Fundamentals and Biomedical Applications, pp. 2140 (Eds DeRossi, D., Kajiwara, K., Osada, Y. and Yamauchi, A.). New York: Plenum PressGoogle Scholar
Schmidt, R. H. & Illingworth, B. L. 1978 Gelation properties of whey protein and blended protein systems. Food Product Development 12(10) 6064Google Scholar
Stading, M. & Hermansson, A.-M. 1990 Viscoelastic behaviour of β-lactoglobulin gel structures. Food Hydrocolloids 4 121135CrossRefGoogle Scholar
Stading, M. & Hermansson, A.-M. 1991 Large deformation properties of β-lactoglobulin gel structures. Food Hydrocolloids 5 339352CrossRefGoogle Scholar
Steventon, A. J. 1993 Thermal Agglomeration of Whey Proteins. PhD thesis, University of Cambridge, UKGoogle Scholar
Steventon, A. J., Gladden, L. F. & Fryer, P. J. 1991 A percolation analysis of the concentration dependence of the gelation of whey protein concentrates. Journal of Texture Studies 22 201218Google Scholar
Stockmayer, W. H. 1943 Theory of molecular size distribution and gel formation in branched-chain polymers. Journal of Chemical Physics 11 4555CrossRefGoogle Scholar
Taylor, S. M. & Fryer, P. J. 1992 Rheology of whey protein concentrates upon heating: influence of the non-protein fraction on gel strength. Entropie 168 5764Google Scholar